esp-idf/components/hal/usb_dwc_hal.c
Tomas Rezucha 72f00d7c6d feat(usb/host): Update ISOC scheduler for HS endpoints
USB-OTG uses 'sched_info' field of HCTSIZ register to schedule transactions
in USB microframes.
2024-03-01 18:05:40 +01:00

534 lines
25 KiB
C

/*
* SPDX-FileCopyrightText: 2020-2024 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <stddef.h>
#include <stdint.h>
#include <string.h> // For memset()
#include <stdlib.h> // For abort()
#include "sdkconfig.h"
#include "soc/chip_revision.h"
#include "soc/usb_dwc_cfg.h"
#include "hal/usb_dwc_hal.h"
#include "hal/usb_dwc_ll.h"
#include "hal/efuse_hal.h"
#include "hal/assert.h"
// ------------------------------------------------ Macros and Types ---------------------------------------------------
// TODO: Remove target specific section after support for multiple USB peripherals is implemented
#include "sdkconfig.h"
#if (CONFIG_IDF_TARGET_ESP32P4)
#define USB_BASE USB_DWC_HS
#else
#define USB_BASE USB_DWC
#endif
// ---------------------- Constants ------------------------
#define BENDPOINTADDRESS_NUM_MSK 0x0F //Endpoint number mask of the bEndpointAddress field of an endpoint descriptor
#define BENDPOINTADDRESS_DIR_MSK 0x80 //Endpoint direction mask of the bEndpointAddress field of an endpoint descriptor
#define CORE_REG_GSNPSID 0x4F54400A //Release number of USB_DWC used in Espressif's SoCs
// -------------------- Configurable -----------------------
/**
* The following core interrupts will be enabled (listed LSB to MSB). Some of these
* interrupts are enabled later than others.
* - USB_DWC_LL_INTR_CORE_PRTINT
* - USB_DWC_LL_INTR_CORE_HCHINT
* - USB_DWC_LL_INTR_CORE_DISCONNINT
* The following PORT interrupts cannot be masked, listed LSB to MSB
* - USB_DWC_LL_INTR_HPRT_PRTCONNDET
* - USB_DWC_LL_INTR_HPRT_PRTENCHNG
* - USB_DWC_LL_INTR_HPRT_PRTOVRCURRCHNG
*/
#define CORE_INTRS_EN_MSK (USB_DWC_LL_INTR_CORE_DISCONNINT)
//Interrupts that pertain to core events
#define CORE_EVENTS_INTRS_MSK (USB_DWC_LL_INTR_CORE_DISCONNINT | \
USB_DWC_LL_INTR_CORE_HCHINT)
//Interrupt that pertain to host port events
#define PORT_EVENTS_INTRS_MSK (USB_DWC_LL_INTR_HPRT_PRTCONNDET | \
USB_DWC_LL_INTR_HPRT_PRTENCHNG | \
USB_DWC_LL_INTR_HPRT_PRTOVRCURRCHNG)
/**
* The following channel interrupt bits are currently checked (in order LSB to MSB)
* - USB_DWC_LL_INTR_CHAN_XFERCOMPL
* - USB_DWC_LL_INTR_CHAN_CHHLTD
* - USB_DWC_LL_INTR_CHAN_STALL
* - USB_DWC_LL_INTR_CHAN_BBLEER
* - USB_DWC_LL_INTR_CHAN_BNAINTR
* - USB_DWC_LL_INTR_CHAN_XCS_XACT_ERR
*
* Note the following points about channel interrupts:
* - Not all bits are unmaskable under scatter/gather
* - Those bits proxy their interrupt through the USB_DWC_LL_INTR_CHAN_CHHLTD bit
* - USB_DWC_LL_INTR_CHAN_XCS_XACT_ERR is always unmasked
* - When USB_DWC_LL_INTR_CHAN_BNAINTR occurs, USB_DWC_LL_INTR_CHAN_CHHLTD will NOT.
* - USB_DWC_LL_INTR_CHAN_AHBERR doesn't actually ever happen on our system (i.e., ESP32-S2, ESP32-S3):
* - If the QTD list's starting address is an invalid address (e.g., NULL), the core will attempt to fetch that
* address for a transfer descriptor and probably gets all zeroes. It will interpret the zero as a bad QTD and
* return a USB_DWC_LL_INTR_CHAN_BNAINTR instead.
* - If the QTD's buffer pointer is an invalid address, the core will attempt to read/write data to/from that
* invalid buffer address with NO INDICATION OF ERROR. The transfer will be acknowledged and treated as
* successful. Bad buffer pointers MUST BE CHECKED FROM HIGHER LAYERS INSTEAD.
*/
#define CHAN_INTRS_EN_MSK (USB_DWC_LL_INTR_CHAN_XFERCOMPL | \
USB_DWC_LL_INTR_CHAN_CHHLTD | \
USB_DWC_LL_INTR_CHAN_BNAINTR)
#define CHAN_INTRS_ERROR_MSK (USB_DWC_LL_INTR_CHAN_STALL | \
USB_DWC_LL_INTR_CHAN_BBLEER | \
USB_DWC_LL_INTR_CHAN_BNAINTR | \
USB_DWC_LL_INTR_CHAN_XCS_XACT_ERR)
// -------------------------------------------------- Core (Global) ----------------------------------------------------
static void set_defaults(usb_dwc_hal_context_t *hal)
{
//GAHBCFG register
usb_dwc_ll_gahbcfg_en_dma_mode(hal->dev);
int hbstlen = 0; //Use AHB burst SINGLE by default
#if CONFIG_IDF_TARGET_ESP32S2 && CONFIG_ESP32S2_REV_MIN_FULL < 100
/*
Hardware errata workaround for the ESP32-S2 ECO0 (see ESP32-S2 Errata Document section 4.0 for full details).
ESP32-S2 ECO0 has a hardware errata where the AHB bus arbiter may generate incorrect arbitration signals leading to
the DWC_OTG corrupting the DMA transfers of other peripherals (or vice versa) on the same bus. The peripherals that
share the same bus with DWC_OTG include I2C and SPI (see ESP32-S2 Errata Document for more details). To workaround
this, the DWC_OTG's AHB should use INCR mode to prevent change of arbitration during a burst operation, thus
avoiding this errata.
Note: Setting AHB burst to INCR increases the likeliness of DMA underruns on other peripherals sharing the same bus
arbiter as the DWC_OTG (e.g., I2C and SPI) as change of arbitration during the burst operation is not permitted.
Users should keep this limitation in mind when the DWC_OTG transfers large data payloads (e.g., 512 MPS transfers)
while this workaround is enabled.
*/
if (!ESP_CHIP_REV_ABOVE(efuse_hal_chip_revision(), 100)) {
hbstlen = 1; //Set AHB burst to INCR to workaround hardware errata
}
#endif //CONFIG_IDF_TARGET_ESP32S2 && CONFIG_ESP32S2_REV_MIN_FULL < 100
usb_dwc_ll_gahbcfg_set_hbstlen(hal->dev, hbstlen); //Set AHB burst mode
//GUSBCFG register
usb_dwc_ll_gusbcfg_dis_hnp_cap(hal->dev); //Disable HNP
usb_dwc_ll_gusbcfg_dis_srp_cap(hal->dev); //Disable SRP
#if (OTG_HSPHY_INTERFACE != 0)
usb_dwc_ll_gusbcfg_set_timeout_cal(hal->dev, 5); // 5 PHY clocks for our HS PHY
usb_dwc_ll_gusbcfg_set_utmi_phy(hal->dev);
#endif // (OTG_HSPHY_INTERFACE != 0)
//Enable interruts
usb_dwc_ll_gintmsk_dis_intrs(hal->dev, 0xFFFFFFFF); //Mask all interrupts first
usb_dwc_ll_gintmsk_en_intrs(hal->dev, CORE_INTRS_EN_MSK); //Unmask global interrupts
usb_dwc_ll_gintsts_read_and_clear_intrs(hal->dev); //Clear interrupts
usb_dwc_ll_gahbcfg_en_global_intr(hal->dev); //Enable interrupt signal
//Enable host mode
usb_dwc_ll_gusbcfg_force_host_mode(hal->dev);
}
void usb_dwc_hal_init(usb_dwc_hal_context_t *hal)
{
//Check if a peripheral is alive by reading the core ID registers
usb_dwc_dev_t *dev = &USB_BASE;
uint32_t core_id = usb_dwc_ll_gsnpsid_get_id(dev);
HAL_ASSERT(core_id == CORE_REG_GSNPSID);
(void) core_id; //Suppress unused variable warning if asserts are disabled
//Initialize HAL context
memset(hal, 0, sizeof(usb_dwc_hal_context_t));
hal->dev = dev;
set_defaults(hal);
}
void usb_dwc_hal_deinit(usb_dwc_hal_context_t *hal)
{
//Disable and clear global interrupt
usb_dwc_ll_gintmsk_dis_intrs(hal->dev, 0xFFFFFFFF); //Disable all interrupts
usb_dwc_ll_gintsts_read_and_clear_intrs(hal->dev); //Clear interrupts
usb_dwc_ll_gahbcfg_dis_global_intr(hal->dev); //Disable interrupt signal
hal->dev = NULL;
}
void usb_dwc_hal_core_soft_reset(usb_dwc_hal_context_t *hal)
{
usb_dwc_ll_grstctl_core_soft_reset(hal->dev);
while (usb_dwc_ll_grstctl_is_core_soft_reset_in_progress(hal->dev)) {
; //Wait until core reset is done
}
while (!usb_dwc_ll_grstctl_is_ahb_idle(hal->dev)) {
; //Wait until AHB Master bus is idle before doing any other operations
}
//Set the default bits
set_defaults(hal);
//Clear all the flags and channels
hal->periodic_frame_list = NULL;
hal->flags.val = 0;
hal->channels.num_allocd = 0;
hal->channels.chan_pend_intrs_msk = 0;
memset(hal->channels.hdls, 0, sizeof(usb_dwc_hal_chan_t *) * OTG_NUM_HOST_CHAN);
}
void usb_dwc_hal_set_fifo_bias(usb_dwc_hal_context_t *hal, const usb_hal_fifo_bias_t fifo_bias)
{
/*
* EPINFO_CTL is located at the end of FIFO, its size is fixed in HW.
* The reserved size is always the worst-case, which is device mode that requires 4 locations per EP direction (including EP0).
* Here we just read the FIFO size from HW register, to avoid any ambivalence
*/
uint32_t ghwcfg1, ghwcfg2, ghwcfg3, ghwcfg4;
usb_dwc_ll_ghwcfg_get_hw_config(hal->dev, &ghwcfg1, &ghwcfg2, &ghwcfg3, &ghwcfg4);
const uint16_t fifo_size_lines = ((usb_dwc_ghwcfg3_reg_t)ghwcfg3).dfifodepth;
/*
* Recommended FIFO sizes (see 2.1.2.4 for programming guide)
*
* RXFIFO: ((LPS/4) * 2) + 2
* NPTXFIFO: (LPS/4) * 2
* PTXFIFO: (LPS/4) * 2
*
* Recommended sizes fit 2 packets of each type. For S2 and S3 we can't fit even one MPS ISOC packet (1023 FS and 1024 HS).
* So the calculations below are compromises between the available FIFO size and optimal performance.
*/
usb_dwc_hal_fifo_config_t fifo_config;
switch (fifo_bias) {
// Define minimum viable (fits at least 1 MPS) FIFO sizes for non-biased FIFO types
// Allocate the remaining size to the biased FIFO type
case USB_HAL_FIFO_BIAS_DEFAULT:
fifo_config.nptx_fifo_lines = OTG_DFIFO_DEPTH / 4;
fifo_config.ptx_fifo_lines = OTG_DFIFO_DEPTH / 8;
fifo_config.rx_fifo_lines = fifo_size_lines - fifo_config.ptx_fifo_lines - fifo_config.nptx_fifo_lines;
break;
case USB_HAL_FIFO_BIAS_RX:
fifo_config.nptx_fifo_lines = OTG_DFIFO_DEPTH / 16;
fifo_config.ptx_fifo_lines = OTG_DFIFO_DEPTH / 8;
fifo_config.rx_fifo_lines = fifo_size_lines - fifo_config.ptx_fifo_lines - fifo_config.nptx_fifo_lines;
break;
case USB_HAL_FIFO_BIAS_PTX:
fifo_config.rx_fifo_lines = OTG_DFIFO_DEPTH / 8 + 2; // 2 extra lines are allocated for status information. See USB-OTG Programming Guide, chapter 2.1.2.1
fifo_config.nptx_fifo_lines = OTG_DFIFO_DEPTH / 16;
fifo_config.ptx_fifo_lines = fifo_size_lines - fifo_config.nptx_fifo_lines - fifo_config.rx_fifo_lines;
break;
default:
abort();
}
HAL_ASSERT((fifo_config.rx_fifo_lines + fifo_config.nptx_fifo_lines + fifo_config.ptx_fifo_lines) <= fifo_size_lines);
//Check that none of the channels are active
for (int i = 0; i < OTG_NUM_HOST_CHAN; i++) {
if (hal->channels.hdls[i] != NULL) {
HAL_ASSERT(!hal->channels.hdls[i]->flags.active);
}
}
//Set the new FIFO lengths
usb_dwc_ll_grxfsiz_set_fifo_size(hal->dev, fifo_config.rx_fifo_lines);
usb_dwc_ll_gnptxfsiz_set_fifo_size(hal->dev, fifo_config.rx_fifo_lines, fifo_config.nptx_fifo_lines);
usb_dwc_ll_hptxfsiz_set_ptx_fifo_size(hal->dev, fifo_config.rx_fifo_lines + fifo_config.nptx_fifo_lines, fifo_config.ptx_fifo_lines);
//Flush the FIFOs
usb_dwc_ll_grstctl_flush_nptx_fifo(hal->dev);
usb_dwc_ll_grstctl_flush_ptx_fifo(hal->dev);
usb_dwc_ll_grstctl_flush_rx_fifo(hal->dev);
hal->fifo_config = fifo_config; // Implicit struct copy
hal->flags.fifo_sizes_set = 1;
}
void usb_dwc_hal_get_mps_limits(usb_dwc_hal_context_t *hal, usb_hal_fifo_mps_limits_t *mps_limits)
{
HAL_ASSERT(hal && mps_limits);
HAL_ASSERT(hal->flags.fifo_sizes_set);
const usb_dwc_hal_fifo_config_t *fifo_config = &(hal->fifo_config);
mps_limits->in_mps = (fifo_config->rx_fifo_lines - 2) * 4; // Two lines are reserved for status quadlets internally by USB_DWC
mps_limits->non_periodic_out_mps = fifo_config->nptx_fifo_lines * 4;
mps_limits->periodic_out_mps = fifo_config->ptx_fifo_lines * 4;
}
// ---------------------------------------------------- Host Port ------------------------------------------------------
static inline void debounce_lock_enable(usb_dwc_hal_context_t *hal)
{
//Disable the hprt (connection) and disconnection interrupts to prevent repeated triggerings
usb_dwc_ll_gintmsk_dis_intrs(hal->dev, USB_DWC_LL_INTR_CORE_PRTINT | USB_DWC_LL_INTR_CORE_DISCONNINT);
hal->flags.dbnc_lock_enabled = 1;
}
void usb_dwc_hal_port_enable(usb_dwc_hal_context_t *hal)
{
usb_dwc_speed_t speed = usb_dwc_ll_hprt_get_speed(hal->dev);
//Host Configuration
usb_dwc_ll_hcfg_set_defaults(hal->dev, speed);
//Configure HFIR
usb_dwc_ll_hfir_set_defaults(hal->dev, speed);
}
// ----------------------------------------------------- Channel -------------------------------------------------------
// ----------------- Channel Allocation --------------------
bool usb_dwc_hal_chan_alloc(usb_dwc_hal_context_t *hal, usb_dwc_hal_chan_t *chan_obj, void *chan_ctx)
{
HAL_ASSERT(hal->flags.fifo_sizes_set); //FIFO sizes should be set befor attempting to allocate a channel
//Attempt to allocate channel
if (hal->channels.num_allocd == OTG_NUM_HOST_CHAN) {
return false; //Out of free channels
}
int chan_idx = -1;
for (int i = 0; i < OTG_NUM_HOST_CHAN; i++) {
if (hal->channels.hdls[i] == NULL) {
hal->channels.hdls[i] = chan_obj;
chan_idx = i;
hal->channels.num_allocd++;
break;
}
}
HAL_ASSERT(chan_idx != -1);
//Initialize channel object
memset(chan_obj, 0, sizeof(usb_dwc_hal_chan_t));
chan_obj->flags.chan_idx = chan_idx;
chan_obj->regs = usb_dwc_ll_chan_get_regs(hal->dev, chan_idx);
chan_obj->chan_ctx = chan_ctx;
//Note: EP characteristics configured separately
//Clean and unmask the channel's interrupt
usb_dwc_ll_hcint_read_and_clear_intrs(chan_obj->regs); //Clear the interrupt bits for that channel
usb_dwc_ll_haintmsk_en_chan_intr(hal->dev, 1 << chan_obj->flags.chan_idx);
usb_dwc_ll_hcintmsk_set_intr_mask(chan_obj->regs, CHAN_INTRS_EN_MSK); //Unmask interrupts for this channel
usb_dwc_ll_hctsiz_set_pid(chan_obj->regs, 0); //Set the initial PID to zero
usb_dwc_ll_hctsiz_init(chan_obj->regs); //Set the non changing parts of the HCTSIZ registers (e.g., do_ping and sched info)
return true;
}
void usb_dwc_hal_chan_free(usb_dwc_hal_context_t *hal, usb_dwc_hal_chan_t *chan_obj)
{
if (chan_obj->type == USB_DWC_XFER_TYPE_INTR || chan_obj->type == USB_DWC_XFER_TYPE_ISOCHRONOUS) {
//Unschedule this channel
for (int i = 0; i < hal->frame_list_len; i++) {
hal->periodic_frame_list[i] &= ~(1 << chan_obj->flags.chan_idx);
}
}
//Can only free a channel when in the disabled state and descriptor list released
HAL_ASSERT(!chan_obj->flags.active);
//Disable channel's interrupt
usb_dwc_ll_haintmsk_dis_chan_intr(hal->dev, 1 << chan_obj->flags.chan_idx);
//Deallocate channel
hal->channels.hdls[chan_obj->flags.chan_idx] = NULL;
hal->channels.num_allocd--;
HAL_ASSERT(hal->channels.num_allocd >= 0);
}
// ---------------- Channel Configuration ------------------
void usb_dwc_hal_chan_set_ep_char(usb_dwc_hal_context_t *hal, usb_dwc_hal_chan_t *chan_obj, usb_dwc_hal_ep_char_t *ep_char)
{
//Cannot change ep_char whilst channel is still active or in error
HAL_ASSERT(!chan_obj->flags.active);
//Set the endpoint characteristics of the pipe
usb_dwc_ll_hcchar_init(chan_obj->regs,
ep_char->dev_addr,
ep_char->bEndpointAddress & BENDPOINTADDRESS_NUM_MSK,
ep_char->mps,
ep_char->type,
ep_char->bEndpointAddress & BENDPOINTADDRESS_DIR_MSK,
ep_char->ls_via_fs_hub);
//Save channel type
chan_obj->type = ep_char->type;
//If this is a periodic endpoint/channel, set its schedule in the frame list
if (ep_char->type == USB_DWC_XFER_TYPE_ISOCHRONOUS || ep_char->type == USB_DWC_XFER_TYPE_INTR) {
unsigned int interval_frame_list = ep_char->periodic.interval;
unsigned int offset_frame_list = ep_char->periodic.offset;
// Periodic Frame List works with USB frames. For HS endpoints we must divide interval[microframes] by 8 to get interval[frames]
if (ep_char->periodic.is_hs) {
interval_frame_list /= 8;
offset_frame_list /= 8;
}
// Interval in Periodic Frame List must be power of 2.
// This is not a HW restriction. It is just a lot easier to schedule channels like this.
if (interval_frame_list >= (int)hal->frame_list_len) { // Upper limits is Periodic Frame List length
interval_frame_list = (int)hal->frame_list_len;
} else if (interval_frame_list >= 32) {
interval_frame_list = 32;
} else if (interval_frame_list >= 16) {
interval_frame_list = 16;
} else if (interval_frame_list >= 8) {
interval_frame_list = 8;
} else if (interval_frame_list >= 4) {
interval_frame_list = 4;
} else if (interval_frame_list >= 2) {
interval_frame_list = 2;
} else { // Lower limit is 1
interval_frame_list = 1;
}
// Schedule the channel in the frame list
for (int i = 0; i < hal->frame_list_len; i+= interval_frame_list) {
int index = (offset_frame_list + i) % hal->frame_list_len;
hal->periodic_frame_list[index] |= 1 << chan_obj->flags.chan_idx;
}
// For HS endpoints we must write to sched_info field of HCTSIZ register to schedule microframes
if (ep_char->periodic.is_hs) {
unsigned int tokens_per_frame;
if (ep_char->periodic.interval >= 8) {
tokens_per_frame = 1; // 1 token every 8 microframes
} else if (ep_char->periodic.interval >= 4) {
tokens_per_frame = 2; // 1 token every 4 microframes
} else if (ep_char->periodic.interval >= 2) {
tokens_per_frame = 4; // 1 token every 2 microframes
} else {
tokens_per_frame = 8; // 1 token every microframe
}
usb_dwc_ll_hctsiz_set_sched_info(chan_obj->regs, tokens_per_frame, ep_char->periodic.offset);
}
}
}
// ------------------- Channel Control ---------------------
void usb_dwc_hal_chan_activate(usb_dwc_hal_chan_t *chan_obj, void *xfer_desc_list, int desc_list_len, int start_idx)
{
//Cannot activate a channel that has already been enabled or is pending error handling
HAL_ASSERT(!chan_obj->flags.active);
//Set start address of the QTD list and starting QTD index
usb_dwc_ll_hcdma_set_qtd_list_addr(chan_obj->regs, xfer_desc_list, start_idx);
usb_dwc_ll_hctsiz_set_qtd_list_len(chan_obj->regs, desc_list_len);
usb_dwc_ll_hcchar_enable_chan(chan_obj->regs); //Start the channel
chan_obj->flags.active = 1;
}
bool usb_dwc_hal_chan_request_halt(usb_dwc_hal_chan_t *chan_obj)
{
if (chan_obj->flags.active) {
/*
Request a halt so long as the channel's active flag is set.
- If the underlying hardware channel is already halted but the channel is pending interrupt handling,
disabling the channel will have no effect (i.e., no channel interrupt is generated).
- If the underlying channel is currently active, disabling the channel will trigger a channel interrupt.
Regardless, setting the "halt_requested" should cause "usb_dwc_hal_chan_decode_intr()" to report the
USB_DWC_HAL_CHAN_EVENT_HALT_REQ event when channel interrupt is handled (pending or triggered).
*/
usb_dwc_ll_hcchar_disable_chan(chan_obj->regs);
chan_obj->flags.halt_requested = 1;
return false;
} else {
//Channel was never active to begin with, simply return true
return true;
}
}
// ------------------------------------------------- Event Handling ----------------------------------------------------
usb_dwc_hal_port_event_t usb_dwc_hal_decode_intr(usb_dwc_hal_context_t *hal)
{
uint32_t intrs_core = usb_dwc_ll_gintsts_read_and_clear_intrs(hal->dev); //Read and clear core interrupts
uint32_t intrs_port = 0;
if (intrs_core & USB_DWC_LL_INTR_CORE_PRTINT) {
//There are host port interrupts. Read and clear those as well.
intrs_port = usb_dwc_ll_hprt_intr_read_and_clear(hal->dev);
}
//Note: Do not change order of checks. Regressing events (e.g. enable -> disabled, connected -> connected)
//always take precedence. ENABLED < DISABLED < CONN < DISCONN < OVRCUR
usb_dwc_hal_port_event_t event = USB_DWC_HAL_PORT_EVENT_NONE;
//Check if this is a core or port event
if ((intrs_core & CORE_EVENTS_INTRS_MSK) || (intrs_port & PORT_EVENTS_INTRS_MSK)) {
//Do not change the order of the following checks. Some events/interrupts take precedence over others
if (intrs_core & USB_DWC_LL_INTR_CORE_DISCONNINT) {
event = USB_DWC_HAL_PORT_EVENT_DISCONN;
debounce_lock_enable(hal);
//Mask the port connection and disconnection interrupts to prevent repeated triggering
} else if (intrs_port & USB_DWC_LL_INTR_HPRT_PRTOVRCURRCHNG) {
//Check if this is an overcurrent or an overcurrent cleared
if (usb_dwc_ll_hprt_get_port_overcur(hal->dev)) {
event = USB_DWC_HAL_PORT_EVENT_OVRCUR;
} else {
event = USB_DWC_HAL_PORT_EVENT_OVRCUR_CLR;
}
} else if (intrs_port & USB_DWC_LL_INTR_HPRT_PRTENCHNG) {
if (usb_dwc_ll_hprt_get_port_en(hal->dev)) { //Host port was enabled
event = USB_DWC_HAL_PORT_EVENT_ENABLED;
} else { //Host port has been disabled
event = USB_DWC_HAL_PORT_EVENT_DISABLED;
}
} else if (intrs_port & USB_DWC_LL_INTR_HPRT_PRTCONNDET && !hal->flags.dbnc_lock_enabled) {
event = USB_DWC_HAL_PORT_EVENT_CONN;
debounce_lock_enable(hal);
}
}
//Port events always take precedence over channel events
if (event == USB_DWC_HAL_PORT_EVENT_NONE && (intrs_core & USB_DWC_LL_INTR_CORE_HCHINT)) {
//One or more channels have pending interrupts. Store the mask of those channels
hal->channels.chan_pend_intrs_msk = usb_dwc_ll_haint_get_chan_intrs(hal->dev);
event = USB_DWC_HAL_PORT_EVENT_CHAN;
}
return event;
}
usb_dwc_hal_chan_t *usb_dwc_hal_get_chan_pending_intr(usb_dwc_hal_context_t *hal)
{
int chan_num = __builtin_ffs(hal->channels.chan_pend_intrs_msk);
if (chan_num) {
hal->channels.chan_pend_intrs_msk &= ~(1 << (chan_num - 1)); //Clear the pending bit for that channel
return hal->channels.hdls[chan_num - 1];
} else {
return NULL;
}
}
usb_dwc_hal_chan_event_t usb_dwc_hal_chan_decode_intr(usb_dwc_hal_chan_t *chan_obj)
{
uint32_t chan_intrs = usb_dwc_ll_hcint_read_and_clear_intrs(chan_obj->regs);
usb_dwc_hal_chan_event_t chan_event;
//Note: We don't assert on (chan_obj->flags.active) here as it could have been already cleared by usb_dwc_hal_chan_request_halt()
/*
Note: Do not change order of checks as some events take precedence over others.
Errors > Channel Halt Request > Transfer completed
*/
if (chan_intrs & CHAN_INTRS_ERROR_MSK) { //Note: Errors are uncommon, so we check against the entire interrupt mask to reduce frequency of entering this call path
HAL_ASSERT(chan_intrs & USB_DWC_LL_INTR_CHAN_CHHLTD); //An error should have halted the channel
//Store the error in hal context
usb_dwc_hal_chan_error_t error;
if (chan_intrs & USB_DWC_LL_INTR_CHAN_STALL) {
error = USB_DWC_HAL_CHAN_ERROR_STALL;
} else if (chan_intrs & USB_DWC_LL_INTR_CHAN_BBLEER) {
error = USB_DWC_HAL_CHAN_ERROR_PKT_BBL;
} else if (chan_intrs & USB_DWC_LL_INTR_CHAN_BNAINTR) {
error = USB_DWC_HAL_CHAN_ERROR_BNA;
} else { //USB_DWC_LL_INTR_CHAN_XCS_XACT_ERR
error = USB_DWC_HAL_CHAN_ERROR_XCS_XACT;
}
//Update flags
chan_obj->error = error;
chan_obj->flags.active = 0;
//Save the error to be handled later
chan_event = USB_DWC_HAL_CHAN_EVENT_ERROR;
} else if (chan_intrs & USB_DWC_LL_INTR_CHAN_CHHLTD) {
if (chan_obj->flags.halt_requested) {
chan_obj->flags.halt_requested = 0;
chan_event = USB_DWC_HAL_CHAN_EVENT_HALT_REQ;
} else {
//Must have been halted due to QTD HOC
chan_event = USB_DWC_HAL_CHAN_EVENT_CPLT;
}
chan_obj->flags.active = 0;
} else if (chan_intrs & USB_DWC_LL_INTR_CHAN_XFERCOMPL) {
/*
A transfer complete interrupt WITHOUT the channel halting only occurs when receiving a short interrupt IN packet
and the underlying QTD does not have the HOC bit set. This signifies the last packet of the Interrupt transfer
as all interrupt packets must MPS sized except the last.
*/
//The channel isn't halted yet, so we need to halt it manually to stop the execution of the next QTD/packet
usb_dwc_ll_hcchar_disable_chan(chan_obj->regs);
/*
After setting the halt bit, this will generate another channel halted interrupt. We treat this interrupt as
a NONE event, then cycle back with the channel halted interrupt to handle the CPLT event.
*/
chan_event = USB_DWC_HAL_CHAN_EVENT_NONE;
} else {
abort();
}
return chan_event;
}